US10594517B1ActiveUtility
Channel estimation system and method thereof
Est. expiryOct 26, 2038(~12.3 yrs left)· nominal 20-yr term from priority
H04L 25/0242H04L 25/021H04L 25/0204H04B 7/0617H04B 7/0413
92
PatentIndex Score
24
Cited by
12
References
26
Claims
Abstract
A channel estimation system and method thereof is provided. By utilizing the nature of the millimeter-wave channel with sparse path, the channel estimation problem is transformed from estimating the entire channel matrix to estimating independent parameters of the millimeter-wave channel. These parameters are angle of arrival (AoA) and angle of departure (AoD), and complex gain of the channel paths.
Claims
exact text as granted — not AI-modifiedWhat is claimed is:
1. A channel estimation system, comprising:
a first transceiver, including a first baseband circuitry and a plurality of first antennas, configured to transmit a downlink omnidirectional signal with one of the plurality of first antennas;
a second transceiver, including:
a plurality of second antennas, configured to receive the downlink omnidirectional signal;
a RF chain circuit coupled to the plurality of first antennas;
a second baseband circuitry, coupled to the RF chain circuit, wherein the first baseband circuitry and the second baseband circuitry are configured to estimate channels by performing the following steps:
obtaining first received signals by processing the downlink omnidirectional signal from the plurality of second antennas,
generating a plurality of receiving array responses corresponding to receiving angles in a determined range of angle, respectively;
estimating an angle of arrival (AoA) by executing an AoA estimating algorithm, wherein the AoA estimating algorithm comprising:
obtaining dot products of the plurality of receiving array responses and the first received signals, respectively; and
selecting one of the receiving angles corresponding to a maximum value among the obtained dot products as the AoA;
using a parameter-separated model to obtain channel complex gains from the first received signals;
providing long-term statistic information associated to the channel complex gains according to structural parameters of the second transceiver;
establishing a Bayesian Linear Estimator to estimate the channel complex gain;
configuring the second transceiver to transmit an uplink omnidirectional signal with one of the plurality of second antennas;
configuring the first transceiver to receive the uplink omnidirectional signal;
obtaining second received signals by processing the downlink omnidirectional signal from the plurality of second antennas,
generating a plurality of transmitting array responses corresponding to transmitting angles in the determined range of angle, respectively;
estimating an angle of departure (AoD) by executing an AoD estimating algorithm, wherein the AoD estimating algorithm comprising:
obtaining dot products of the plurality of transmitting array responses and the second received signals, respectively; and
selecting one of the transmitting angles corresponding to a maximum value among the obtained dot products as the AoD; and
obtaining a channel matrix according to the estimated AoA, the channel complex gain, and the estimated AoD.
2. The channel estimation system according to claim 1 , wherein the first received signal is represented as an equation (1):
y=Σ i,l α i,l a r (ϕ il )+ n (1),
wherein α i,l is a channel complex gain, ϕ il is an angle of arrival, a r (ϕ il ) is a receiving array response, and n is a Gaussion noise.
3. The channel estimation system according to claim 2 , wherein the AoA estimating algorithm is represented as an equation (2):
=
arg
s
max
a
r
H
(
)
y
(
2
)
,
wherein is the estimated angle of arrival.
4. The channel estimation system according to claim 2 , wherein the AoD estimating algorithm is represented as an equation (5):
=
arg
s
max
θ
il
a
t
H
(
θ
il
)
y
(
5
)
,
wherein is the estimated angle of departure, a t is transmitting array response, and y is the second received signal.
5. The channel estimation system according to claim 1 , wherein the parameter-separated model is represented as an equation (3):
y=A r α+n (3),
wherein A r is a received array response matrix, α is a vector of the channel complex gain, n is a vector of the Gaussian noise.
6. The channel estimation system according to claim 5 , wherein the Bayesian Linear Estimator is represented by an equation (4):
{circumflex over (α)}=μ α +C α A r H ( A r C α A r H +C n ) −1 ( y−A r μ α ) (4);
wherein μ α is mean value vector of the channel complex gain, C α is a covariance matrix of the channel complex gain, A r is the received array response matrix, y is a vector of the first received signal.
7. The channel estimation system according to claim 1 , wherein the channel matrix is represented by an equation (6):
H=Σ i,l α i,l a r (ϕ il ) a t (θ il ) H , [ N r ,N t ]=dim( H ) (6),
wherein α il is the channel complex gain of a lth path of an ith scattering group, N t is a number of the first antennas, N r is a number of the second antennas, ϕ il is the AoA, θ il is the AoD, a r (ϕ il ) is the receiving array response, and a t (θ il ) is the transmitting array response.
8. The channel estimation system according to claim 1 , wherein the RF chain circuit comprising:
a plurality RF chain units coupled between the second baseband circuitry and the plurality of second antennas, wherein each of the RF chain units including:
an amplifier coupled to one of the second antennas;
a first mixer coupled to the amplifier; and
a first digital/analog (D/A) converter coupled to the first mixer and the second baseband circuitry.
9. The channel estimation system according to claim 1 , wherein the RF chain circuit comprising:
a plurality amplifiers respectively coupled to the plurality of second antennas;
a plurality of phase shifters respectively coupled to the plurality amplifiers;
a second mixer coupled to the first group of the amplifiers;
a third mixer coupled to the second group of the amplifiers; and
a plurality of second D/A respectively coupled to the second mixer, the third mixer and the second baseband circuitry.
10. The channel estimation system according to claim 9 , further comprising a gain controller for respectively controlling gains of the plurality of phase shifters, wherein the received signal is further represented by an equation (7):
y j =W j H [Σ i,l α i,l a r (ϕ il )+ n ], j= 1,2, . . . , N r (7)
wherein Nr is the number of the second antennas, Wj is vector of gains of the plurality of phase shifters, wherein Wj is further represented by an equation (8):
W
j
=
[
0
,
0
,
…
0
,
1
,
0
,
…
,
0
]
T
,
W
(
k
)
=
{
0
,
k
≠
j
1
,
k
=
j
.
(
8
)
11. The channel estimation system according to claim 1 , wherein the long-term statistic information associated to the channel complex gain includes probability density functions, mean values, variance values of the channel complex gain.
12. The channel estimation system according to claim 1 , wherein a dimension of the transmitting array response is N r ×1, and a dimension of the receiving array response is N t ×1, where N t is the number of the first antennas, N r is the number of the second antennas.
13. The channel estimation system according to claim 1 , wherein the channel matrix consists of N cl scattering groups, and each of the N cl scattering groups consists of N ray transmission paths, and the equation (3) is further represented by an equation (9):
y
=
A
r
α
+
n
=
A
r
[
α
i
,
1
α
i
,
2
⋮
α
i
,
N
ray
]
+
n
(
9
)
wherein A r is the receiving array response matrix with a dimension of N r ×N ray , α is the vector of the channel complex gain with a dimension of N ray ×1, and n is a vector of the gauss noise with a dimension of N r ×1.
14. A channel estimation method, comprising:
configuring a plurality of first antennas of a first transceiver to transmit a downlink omnidirectional signal with one of the plurality of first antennas, wherein the first transceiver further includes a first baseband circuitry;
configuring a plurality of second antennas of a second transceiver to receive the downlink omnidirectional signal, wherein the second transceiver further includes a RF chain circuit coupled to the plurality of first antennas, and a second baseband circuitry coupled to the RF chain circuit;
configuring the first baseband circuitry and the second baseband circuitry to estimate channels by performing the following steps:
obtaining first received signals by processing the downlink omnidirectional signal from the plurality of second antennas,
generating a plurality of receiving array responses corresponding to receiving angles in a determined range of angle, respectively;
estimating an angle of arrival (AoA) by executing an AoA estimating algorithm, wherein the AoA estimating algorithm comprising:
obtaining dot products of the plurality of receiving array responses and the first received signals, respectively; and
selecting one of the receiving angles corresponding to a maximum value among the obtained dot products as the AoA;
using a parameter-separated model to obtain channel complex gains from the first received signals;
providing long-term statistic information associated to the channel complex gains according to structural parameters of the second transceiver;
establishing a Bayesian Linear Estimator to estimate the channel complex gain;
configuring the second transceiver to transmit an uplink omnidirectional signal with one of the plurality of second antennas;
configuring the first transceiver to receive the uplink omnidirectional signal;
obtaining second received signals by processing the downlink omnidirectional signal from the plurality of second antennas,
generating a plurality of transmitting array responses corresponding to transmitting angles in the determined range of angle, respectively;
estimating an angle of departure (AoD) by executing an AoD estimating algorithm, wherein the AoD estimating algorithm comprising:
obtaining dot products of the plurality of transmitting array responses and the second received signals, respectively; and
selecting one of the transmitting angles corresponding to a maximum value among the obtained dot products as the AoD; and
obtaining a channel matrix according to the estimated AoA, the channel complex gain, and the estimated AoD.
15. The channel estimation method according to claim 14 , wherein the first received signal is represented as an equation (1):
y=Σ i,l α i,l a r (ϕ il )+ n (1),
wherein α i,l is a channel complex gain, ϕ il is an angle of arrival, a r (ϕ il ) is a receiving array response, and n is a Gaussian noise.
16. The channel estimation method according to claim 15 , wherein the AoA estimating algorithm is represented as an equation (2):
=
arg
s
max
a
r
H
(
)
y
(
2
)
,
wherein is the estimated angle of arrival.
17. The channel estimation method according to claim 15 , wherein the AoD estimating algorithm is represented as an equation (5):
=
arg
s
max
θ
il
a
t
H
(
θ
il
)
y
(
5
)
,
wherein is the estimated angle of departure, a t is transmitting array response, and y is the second received signal.
18. The channel estimation method according to claim 14 , wherein the parameter-separated model is represented as an equation (3):
y=A r α+n (3),
wherein A r is a received array response matrix, α is a vector of the channel complex gain, n is a vector of the gauss noise.
19. The channel estimation method according to claim 18 , wherein the Bayesian Linear Estimator is represented by an equation (4):
{circumflex over (α)}=μ α +C α A r H ( A r C α A r H +C n ) −1 ( y−A r μ α ) (4);
wherein μ α is mean value vector of the channel complex gain, C α is a covariance matrix of the channel complex gain, A r is the received array response matrix, y is a vector of the first received signal.
20. The channel estimation method according to claim 14 , wherein the channel matrix is represented by an equation (6):
H=Σ i,l α i,l a r (ϕ il ) a t (θ il ) H , [ N r ,N t ]=dim( H ) (6),
wherein α il is the channel complex gain of a lth path of an ith scattering group, N t is a number of the first antennas, N r is a number of the second antennas, ϕ il is the AoA, θ il is the AoD, a r (ϕ il ) is the receiving array response, and a t (θ il ) is the transmitting array response.
21. The channel estimation method according to claim 14 , wherein the RF chain circuit comprising:
a plurality RF chain units coupled between the second baseband the plurality of second antennas, wherein each of the RF chain units including:
an amplifier coupled to one of the second antennas;
a first mixer coupled to the the amplifier; and
a first digital/analog (D/A) converter coupled to the first mixer and the second baseband circuitry.
22. The channel estimation method according to claim 14 , wherein the RF chain circuit comprising:
a plurality amplifiers respectively coupled to the plurality of second antennas;
a plurality of phase shifters respectively coupled to the plurality amplifiers;
a second mixer coupled to the first group of the amplifiers;
a third mixer coupled to the second group of the amplifiers; and
a plurality of second D/A converter respectively coupled to the second mixer, the third mixer and the second baseband circuitry.
23. The channel estimation method according to claim 22 , further comprising a gain controller for respectively controlling gains of the plurality of phase shifters, wherein the received signal is further represented by an equation (7):
y j =W j H [Σ i,l α i,l a r (ϕ il )+ n ], j= 1,2, . . . , N r (7)
wherein N r is the number of the second antennas, W j is vector of gains of the plurality of phase shifters, wherein W j is further represented by an equation (8):
W
j
=
[
0
,
0
,
…
0
,
1
,
0
,
…
,
0
]
T
,
W
(
k
)
=
{
0
,
k
≠
j
1
,
k
=
j
.
(
8
)
24. The channel estimation method according to claim 14 , wherein the long-term statistic information associated to the channel complex gain includes probability density functions, mean values, variance values of the channel complex gain.
25. The channel estimation method according to claim 14 , wherein a dimension of the transmitting array response is N r ×1, and a dimension of the receiving array response is N t ×1, where N t is the number of the first antennas, N r is the number of the second antennas.
26. The channel estimation method according to claim 14 , wherein the channel matrix consists of N cl scattering groups, and each of the N cl scattering groups consists of N ray transmission paths, and the equation (3) is further represented by an equation (9):
y
=
A
r
α
+
n
=
A
r
[
α
i
,
1
α
i
,
2
⋮
α
i
,
N
ray
]
+
n
(
9
)
wherein A r is the receiving array response matrix with a dimension of N r ×N ray , α is the vector of the channel complex gain with a dimension of N ray ×1, and n is a vector of the gauss noise with a dimension of N r ×1.Cited by (0)
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